CZ297617B6 - LED lamp and method for safe control of such LED lamp - Google Patents

Abstract

In the present invention, there is disclosed a LED lamp of outdoor light signaling system in a railway safety hardware, said LED lamp being intended for a crossing interlocking device and/or for station and section blocking wherein such lamp is provided with LEDs (4) distributed in sections (9) and the lamp comprises control and supervising circuits and a power source (11) functioning as a feeding section. The invented LED lamp is divided into three independent and electrically separated sections (9) of LEDs (4), wherein light of even two sections (9) of LEDs is sufficient for meeting the required optical properties of the LED lamp at maintenance of safety for allowing and inhibiting signs. Each LED section (9) has an independent supply circuit (12); each LED section (9) comprises three independent supervisions. Output signals of each independent supervision are applied to another control circuit of the LED sections (9). Each LED section (9) is provided with a feed breaking element (1) of each adjacent section (9). There is also disclosed a method for safe control of the above-described LED lamp wherein the method comprises execution of functionality check of the LEDs (4) and functionality check of control and supervision electronics of each section of the LED lamp. The LED lamp functionality check is carried out by continuously checking each circuit of the LEDs (4) and simultaneously by the three independent supervisions as well as by a continuous check of the functionality of the control and supervision electronics of each section (9) of the LED lamp. During the checks, there is detected each individual fault occurred in one of the circuits comprising a LED lamp control circuit, a LED lamp supervision circuit, a power supply (11) circuit and a LEDs (4) circuit. Subsequently, the detection of a fault is transmitted in a safe manner to a superior system for indication thereof. At the same time, the LED lamp remains fully functional according to appropriate standards at maintaining safety principles for both allowing and inhibiting signs.

Description

LED flashlight and how to safely operate this LED flashlight

Technical field

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an LED light for outdoor light signaling in railway signaling, particularly for level crossing and / or station and track signaling, with LEDs divided into sections and comprising control and supervision circuits and a power supply part.

The invention also relates to a method for the safe operation of this LED lamp, in which the functionality of the LEDs is checked and the functionality of the control and supervisory electronics of each section of the LED lamp is checked.

BACKGROUND OF THE INVENTION

Currently used outdoor signal lamps within Czech Railways are almost exclusively incandescent. The light bulb, as a light source for the security device, appears to be disadvantageous due to the very low reliability given by the design and lighting principle. This feature is eliminated in two possible ways for the safety of railway operation.

Double-filament lamps are used for level crossing safety devices, ie for warning devices.

If the main filament of the bulb is burnt, the replacement filament is automatically switched to.

In other areas of outdoor signaling of railway signaling equipment, ie in the case of signals, in case of burning of a single filament of the bulb, the principle of lighting of the less permitting sign is used.

Another important factor in the use of incandescent lamps is the relatively high energy intensity of such a light source.

The controls and all the logic of the incandescent lamps are generally located outside the light signal or warning signs. Corresponding electronics are formed in older types of devices by relay circuits and in newer types of combinations of processor systems in combination with contact or contactless interface. When checking the lighting of bulbs, the principle of current supervision through the bulb is used. (In addition, J sensors are commonly used as optical sensors located in lamps, the outputs of which give information about the lighting of the lamp bulbs. Based on this input information, the relay or processor logic evaluates the function of the lamps. or a light-emitting light of a light-emitting feature on a light bulb.

Due to the smallest voltage drop distributed over long distances, the power supply of the signal lamps is solved by an alternating voltage of 230 V / 50 Hz. This voltage is then transformed by a transformer located near or near the signal to the power supply voltage of a particular 12 V / 20 W signal lamp.

The rated power supply of the incandescent lamp lamps is derived from the logic power supply voltage, either relay or processor, controlling the 24 V DC lamps. Dual-filament bulbs are 2x 12 V, 20 W.

For the above-mentioned reasons, the first lamps equipped with LEDs are beginning to appear within the Czech Railways. For the time being, these are only speed indicators, which are numbers (character) or band (symbol). The lighting control of this light is solved by connecting or disconnecting the power supply. Its supervision consists of one current relay, which in case of insufficient current through its waste indicates no

The state of the lamp when illuminated. Principal connection of LEDs within this lamp is classic, parallel-parallel, with direct mutual influence of individual LEDs.

Abroad, the production of LED lamps for railway signaling equipment is engaged in companies such as 5 Alstom, Ansaldo, Safetran, Westinghouse, Percept and others.

These lamps usually use again a series-parallel combination of individual LEDs, in some manufacturers divided into two parallel sections with independent power supply and control. For maximum compatibility with incandescent lamps, control is provided by connecting the power supply when the lamp is on, or by disconnecting the power supply when the lamp goes out. The power supply voltage of these foreign lamps varies by manufacturer, with the possibility of supplying DC or AC voltage depending on the type of lamp. The power supply and therefore the control of these foreign LED lamps is usually only two-wire and non-redundant.

The control of the LED light is advantageously solved by the products of these foreign companies by checking the total current of the lamp with low sensitivity and thus detecting the failure of up to a large number of LEDs. Great emphasis is placed on the reliability of the LED itself. Of course, when two parallel LED sections are powered by two independent sources, the failure of each of these sources is detected.

A common feature of the above mentioned LED lamp control and supervision systems is their indisputable increase in reliability over incandescent lamps, based on the generally valid and physically based fact that the lamp has far less reliability than the reliability of even a larger number of LEDs, in this case of the order of 200. forming one lamp. However, there is no desirable increase in availability, ie availability, compared to 25 incandescent lamps. It is only a 1-in-1 system (“lool”), with partial possibility of monitoring the LED function by using current draw. Furthermore, only the principle of switching contact or contactless commanding of remote lighting with decision, tripping and diagnostic logic located in a remote object is used here. This entails great demands for sufficient cabling, which has a significant effect on the overall cost of the alarm system.

E.g. in patent application EP 132 4641 of Applicant Westinghouse Brake & Signal Holdings Ltd., GB, the task of electrical arrangement and monitoring of the LED lamp light current is addressed. The signal lantern, which is intended solely as a direct replacement for the 35 incandescent lamp lantern in terms of power and control, is composed of at least two separate LED arrays with their own control circuits connected in parallel. Due to the current passing through these LED fields, a load resistor is automatically connected in parallel to the lamp power supply, which causes the LED lamp to be drawn as if it were incandescent. The evaluation of lamp functionality by current relays is the same as for incandescent lamps. The circuit of automatic connection of the load resistor consists of 40 pairs of optocouplers for one LED field. Non-conforming LED arrays, ie not illuminating one or more LED arrays, are evaluated by a separate relay as a “non-urgent alarm”. This evaluation circuit is not a "fail-safe" circuit. Therefore, the main emphasis here is on the evaluation of non-lighting any field LED by an observer, for example. driver. For this reason, the arrangement of the individual LED fields within the lamp 45 must be such that the failure of any of them can be discernible to the human eye.

The advantage of this solution is the possibility of simple replacement of the LED lamp with the existing incandescent lamp without the need to modify the control and supervision circuits of the signal lamp. The principle of this solution is based on the same LED lamp consumption as incandescent lamps, so there is no energy saving. Another drawback mentioned in the present invention is that the character of the tracing circuit is less reliable than the circuit used to evaluate the lighting of incandescent lamps. Another disadvantage is safety based on the human factor, where the monitoring circuit of the LED lamp evaluation is not "fail - safe", ie the circuit with its own safety. The identification of the illumination of one field of the LED lamp is carried out by the driver simply by visual observation. In the event of failure of the LED array 55, the optical parameters placed on the signal lantern do not seem to be met.

The Czech utility model CZ-Ul-14 134 of Betamont s.r.o., SK, describes the wiring of an electronic supervisory circuit for level crossing warning devices, solving the task of supplying and checking the warning lights, consisting of a matrix of LEDs. The LED matrix is divided into two independent series strings. Each of them is powered by a separate power supply. Checking the luminous intensity of the LEDs is based on monitoring the current flowing through the LED series through a safe level circuit. The current in each branch is monitored separately. The current control is complemented by a voltage level check between the two LED strings. The current monitoring of both LED branches and voltage monitoring are evaluated together in a safe logic product circuit, whose output static signal serves to drive the resulting control group I safety relay. The static output signal is only generated when all inputs are excited by the safe level circuit output signals, ie by checking the current of both strings and voltage.

Also, this solution allows the LED lamp to be replaced with a incandescent lamp without any modification of the control circuits of the warning lamp, but with the minimum of modifications in the tracing of the lighting of the warning lamp lamps.

The disadvantage of this solution is the low availability of the alert. The first failure of the LED lamp already means a failure condition. A further disadvantage is the static output signal of the supervision when both warning lamps are lit, resulting in poor information reliability. The wiring is solved only by warning lamps, while the supply voltage is only 12 V with the specified unspecified allowed range.

In Japanese patent JP 2000172986 the owner of Nippon Signal Co. Ltd., JP, describes a solution for a signal lantern fault detector that is capable of detecting a failure, i.e., breaking the LEDs and reducing their glow caused by their aging. LED signaling lamps are connected in parallel. There is a LED for monitoring the luminous intensity of the signaling LEDs in each serial branch. This monitoring LED is from the same production series as the signaling LED. The monitoring LED is located on the same substrate as the signaling LEDs. The luminous intensity of the monitoring LED is sensed, in principle in the form of an optocoupler, by an evaluation circuit. If it is assumed that thanks to the same production technology, all these LEDs will age the same and their luminance will decrease with time, the luminance of signaling LEDs is determined or rather estimated and therefore their luminous intensity level is determined. In case of interruption of any LED in the serial line, the monitoring LED will no longer light, which is also detected by the evaluation circuit. The output of the evaluation circuits of all series LED strings is combined in a single gate whose output is connected to a signaling relay.

It is simply monitoring the supply current of several LED strings and checking whether the current is flowing or not. It is also estimated to reduce the luminous intensity of LEDs due to their aging. The designed circuit does not address the indication of the short circuit of the diodes (s) of each series branch, nor does it increase the availability of the lamps. The LED lighting supervision circuit is not solved by the fail safe principle.

SUMMARY OF THE INVENTION

The aforementioned disadvantages are avoided or substantially reduced by the proposed intelligent LED lamp according to the invention, which is characterized in that the LED lamp is divided into three independent and electrically separated LED sections, even if the light of only two sections is sufficient to meet the relevant standards concerning the optical characteristics of the lamp, while maintaining the safety for the authorizing and prohibiting signs. Each of the three LED sections has an independent power circuit, each LED section contains three independent supervisions, each independent supervision output is fed to the control circuit of another LED section, and each control circuit is equipped with a power cut-off element for adjacent LED sections.

-3GB 297617 B6

The main advantage of the present invention is that this intelligent LED flashlight operates on the "2oo3" system principle, ie two out of three.

The advantage of this intelligent LED lamp according to the invention is that

- significantly increases the availability or readiness of outdoor light signaling in rail traffic (A _s = 0.999999), both with regard to road users at level crossing safety equipment and with regard to rail transport in station, line and level crossing safety equipment , io - increases the functional reliability of traffic lights and warning lights,

- reduces the cost of the overall cabling of security equipment,

- reduces maintenance costs for traffic lights and warning lights,

- allows connection to modern alarm control systems,

- takes over and safely controls the functions of the control, supervision and supervision of the lighting of each individual lamp from the higher-level systems.

Advantageously, the independent supervision is at least one current supervision which in the simplest way allows control of the LED illumination. Independent supervision may also be voltage supervision or optical supervision.

The independent supervision may be at least one LED control and monitoring circuit, which is an optimal combination of another LED control and control function in one circuit.

Independent supervision can also be created by two LED current supervision and one LED control and monitoring circuit, which is a convenient arrangement for a LED rail lamp.

Preferably, the control circuit is a control processor that combines control functions and evaluation functions of all supervisory elements. The control circuit may also be formed from discrete semiconductor circuits or relay circuits.

In a particular long-tested and preferred arrangement, the independent current supervision has output to the control processor of the first adjacent LED section, the second independent current supervision has output to the control processor of the second adjacent LED section, and the control circuit and LED monitoring function create LED control of its own LED section diod. This ensures independent monitoring and independent evaluation of the status of all LEDs.

The disconnecting element of the power supply of the LED sections is the block of disconnecting the power supply of the LEDs. Such a shut-off element prevents the confusion of a confusing light signal which may lead to a hazardous traffic situation, for example the self-illumination of the multi-permitting feature.

Each of the three sections is equipped with bidirectional data communication with the superior system, serving for the transmission of command and diagnostic information.

Advantageously, the data communication is physically redundant with the concurrent active state, resulting in an increased readiness of the LED lamp.

Each LED section has a control circuit equipped with bidirectional transverse communication to enable communication with the control circuits of the two remaining two LED sections.

The power supply is connected to two power supply systems that ensure the stability of the LED lamp. Thus, the LED torch is adapted to power from two independent external power assemblies, resulting in increased availability of the device.

-4GB 297617 B6

The principle of the safe operation of this intelligent LED lamp according to the invention is that it is carried out by inspecting LEDs divided into three independent and electrically separated sections, continuously and simultaneously by three independent supervisors, while simultaneously monitoring the functionality of the control and supervisory electronics of each LED section . These checks detect any one fault occurring in one of the circuits, including the LED lamp control circuit, the LED lamp control circuit, the source circuit, and the LED circuit. Subsequently, the detection of this fault is safely transferred to the master system for its indication. The LED flashlight remains fully functional according to the relevant standards while maintaining the safety principles for both the permitting and prohibiting sign.

The main advantage of this method according to the invention is that the illumination of only two sections is sufficient to satisfy the relevant standards regarding the optical properties of the LED lamp and therefore this arbitrary one failure does not cause the whole LED lamp to fail. The division of the LEDs into three electrically separated sections guarantees the independence of the sections. Continuous and simultaneous LED checks ensure safe LED lamp monitoring. Fault detection of one section is transmitted to the master system, where it is indicated and evaluated. Importantly, failure of one section of LEDs will not cause the entire lamp to fail.

It is advantageous to maintain the independence of the function information of each LED when the function of the LEDs in each section is controlled and supervised by a separate control circuit based on information from the superior system and diagnostic information from that section and from both adjacent sections.

For consistent independence and to ensure the safe operation of the LED lamp, it is advantageous if the control circuit from three independent sources receives information about the function of each LED of any one section of the three sections from the control and monitoring circuit of the LEDs of that section communicating with the control circuit of the other arbitrary section of the two remaining sections and of bi-directionally transverse communication with the control circuit of the remaining last third section. Each control circuit of one arbitrary section receives information transmitted by bi-directional transverse communication about the function of the LEDs of the two remaining sections from the current supervision of those adjacent sections. The function of each LED is evaluated independently in all three control circuits, with the resultant data being exchanged via bi-directional transverse communication.

Regardless of information from the master system in the event of failure of one section of the enabling LED lamp, or even without the information of the control circuits of the two remaining sections, the control circuits disconnect the power supply of the section LEDs with the detected fault. This ensures that the power supply of each LED section is switched off by the control circuit of the adjacent section without logical matching of the remaining sections, so that even one LED section of the enabling lamp is not accidentally lit.

Regardless of information from the master system in the event of a failure of one section of the LEDs of the prohibiting sign and following the information of the control circuits of the two remaining sections, the control circuits disconnect the power supply to the sectioned LEDs. In case of unwanted illumination of one section of the LED of the prohibiting sign, it is thus possible to switch off the power supply of LEDs of this section after logical agreement of the control circuits of the remaining sections. It is impossible to switch off even one section of LEDs due to failure of any control circuit.

The control circuit communicates bidirectionally with the higher-level system exclusively via secure data communication that is physically redundant with the concurrent active state. This ensures the transmission of the necessary signals even after interruption of one of the communication lines.

Each LED lamp section is powered separately to maintain the system (“2oo3”), ie two out of three.

The power supply creates two separate power supply circuits of the LED lamp sections from the two input power supply systems, and failure of any one of the two input power supply systems results in the failure of only one of the three separate power supply lamp LED circuits, the optimal solution for system selection (2oo3) ).

BRIEF DESCRIPTION OF THE DRAWINGS

An exemplary embodiment of the invention is described in detail below and illustrated by means of schematic drawings, in which Fig. 1 is a block diagram of one LED lamp section and Fig. 2 is a block diagram of an LED lamp.

DETAILED DESCRIPTION OF THE INVENTION

FIG. 1 schematically shows an exemplary block diagram of one of the three sections 9 of an intelligent LED lamp, with a power supply 1 of LEDs 4 and with two series-connected current supervision 3 LEDs. The outputs 2 of the current supervision 3 are connected to the adjacent LED sections 9 according to FIG.

2. LED control 4 section 9 The LED provides a control and monitoring circuit 5 that communicates with the control processor 7. Based on the transverse communication 6 and the outputs 2 of the current 20 supervisors 3 the control circuit LEDs preferably the control processor 7 allows to activate the power disconnection block 13 adjacent section of 9 LEDs. Two-way data communication 8 with the master system controls the operation of the entire LED section 9.

Fig. 2 shows the interconnection of all three sections 9. The sections 9 are interconnected by a transverse 25 communication 6, on the other hand by the outputs 2 of the current supervision LEDs and by the control of the block 13 of the disconnection of the LEDs. The power circuits 12 of the LED sections 9 are formed in the power supply 11 from two independent power systems 10.

All the LEDs 4 of one LED lamp are divided into three independent LED sections 9 and 30 are arranged in such a way that the illumination of only two of the three LED sections 9 satisfies all the requirements of the corresponding standards for the optical properties of the lamp. The LEDs 4 are controlled by the LED control and monitoring circuits 5, allowing independent power supply 1 of the LED section 9 to each other. Thus, any fault, i.e., disconnection or short circuit, of any LED 4 will not affect the LEDs of the other 4 LEDs. their optical and reliability parameters. These LED control circuits 5 also enable monitoring of their functionality. Any failure of the connected LED 4, ie disconnection but also short circuit, is detected and this information is transmitted to the control processor 7. Each LED section 9 has its own independent control processor 7. The independent control processor 7 processes the command information coming from the master system , bidirectional communications 8, such as "turn on light", "turn on oscillating light", "turn off 40 light" and so on. At the same time, the independent control processor 7 further processes the information from the circuits 5 controlling and monitoring the LEDs of its section 9. At the same time, the independent control processor 7 also processes information from the transverse communication 6 between all three control processors 7 as well LEDs of both adjacent sections 9 LEDs. The current supervision of the 3 LEDs senses the total current drawn of the respective section 9 of the LEDs. By processing all this information, the function and instantaneous status information of each individual LED 4, each control and monitoring circuit 5, and each control processor 7 is unambiguously detected.

In order to prevent the corresponding section 9 of the LED indicator light enabling the sign, eg the signal, from being illuminated at the moment it is to be extinguished, due to the failure of the decision or triggering part of the device consisting of the control processor 7 and 50 for each control processor 7 to permanently disconnect the power to the LEDs 4 of the adjacent sections 9 by the block 13 to disconnect the power to the LEDs 4 in the flashlight enabling the character regardless of the remaining control processors 7.

-6GB 297617 B6

In order to prevent the switching off of more than one section 9 of the LED indicator light, such as a signal, due to a failure of the decision-making or equipment part of the control processor 7 and the LED control and monitoring circuits 5, only two control processors 7 are allowed their conformity, i.e. after the logic product, permanently disconnect the LED power supply 4 of the third section 9 in the lamp prohibiting character by block 13 of the disconnection of the LED power supply 4.

The power supply of the individual LED sections 9, including the control and supervisory electronics, is solved separately, ie the output of the block of the power supply 11 is three independent power circuits of 12 LED sections 9. The two applied input voltage of the power supply systems 10, i.e. different or uniform power supply systems of any combination of AC and / or DC as needed, are transformed within the power supply 11 into three output circuits 12 of the LED sections 9 in such a way that 10 results in the failure of only 1/3 of the power supply circuits of the 12 LED sections 9, whereby all the requirements of the corresponding standards for the optical properties of the lamp are maintained. The functionality of the individual necessary circuits of the power supply block 11 is constantly tested by the control processors 7 of the individual LED sections 9.

Command information coming from communication 8 with the master system, eg "turn on the light", "turn on the oscillating light", "turn off the light", etc., and at the same time diagnostic information sent to the master system 8, eg "light on", "light off" "," Trouble-free state "," fault "and its type, etc., are transmitted exclusively via data communication 8. This communication 8 is physically redundant, representing two independent lines with concurrent active state.

An exemplary particular embodiment is one of many possible embodiments. Other embodiments within the scope of the invention are possible.

Industrial applicability

The level crossing device is a red and white LED warning light.

The station and trackside signaling equipment shall be the red, yellow, green, blue and white LED lights of the main lights, ie the entry, departure, road, sectional and cover signals of the main lights, repeaters of the main lights, marshalling lights, marsh repeaters, signaling points and repeaters.

Claims (19)

1. Outdoor light signaling LED lamp in railway signaling, intended in particular for level crossing and / or station and line signaling, with LEDs (4) divided into sections (9), comprising control and supervision circuits and a source (11) as a power section, characterized in that it is divided into three independent and electrically separated LED sections (9), wherein the light of the two LED sections (9) is sufficient to meet the required optical properties of the LED lamp, while maintaining safety for an enabling and disabling feature, each LED section (9) has an independent power supply circuit (12), each LED section (9) comprises three independent supervisors, the output of each independent supervision is fed to a different control circuit of the LED sections (9), and each section (9) The LED is equipped with a power cut-off element (1) for each of the adjacent sections (9). -7EN 297617 B6 LED lamp according to claim 1, characterized in that the independent supervision is at least one current supervision (3) of the LED. 3. The LED lamp according to claim 1, wherein the independent supervision is the 5 less one LED control and monitoring circuit (5). LED lamp according to claim 1, characterized in that the control circuit is a control processor (7). io LED lamp according to claim 1, characterized in that the switching-off element of the power supply (1) is a power supply block (13) of each of the adjacent LED sections (9) controlled from the control circuits of both adjacent sections (9) LED. LED lamp according to claim 1, characterized in that each LED section (9) has its 15 control circuit equipped with bidirectional data communication (8) with a superior system. LED lamp according to claim 6, characterized in that the data communication ( 8) is physically redundant with concurrent active state. An LED lamp according to claim 1, characterized in that each LED section (9) has a control circuit equipped with a bidirectional transverse communication (6) to enable communication with the control circuits of the two remaining sections (9). ICE. LED lamp according to claim 1, characterized in that the power supply (11) is connected to two power supply systems (10). LED lamp according to claim 2 or 3, characterized in that the three independent supervisors are formed by two LED current supervisors (3) and one LED control and monitoring circuit (5). LED lamp according to claim 10, characterized in that one of the independent LED current supervision (3) has its output (2) connected to the control circuit of one adjacent LED section (9), the remaining second independent current supervision (3) has an output (2) applied to the control circuit of the remaining second adjacent LED section (9), the LED control and monitoring circuit (5) for 35 Creating an LED Control (4) of the Own Section (9) The LED is connected to the control circuit of the own LED section (9) and that two control current outputs (3) of the remaining two LED sections (9) are fed to this control circuit. . LED lamp according to claim 1, characterized in that the switching element is a power supply 40 (1) The LEDs (4) are the LED power block (13). A method for safely controlling an LED lamp according to claims 1 to 12, wherein the function of the LEDs (4) is checked and the function of the control and supervisory electronics of each section of the LED lamp is checked, 45 the role of each LED circuit (4) continuously and at the same time by three independent supervisors and at the same time by continuously checking the functionality of the control and supervisory electronics of each section (9) of the LED lamp; LED lamp, LED lamp supervision circuit, source circuit (11) and LED circuit (4), then the fault detection is safely transferred to the master system for its indication, while the LED lamp remains fully functional according to the relevant standards while maintaining safety principles for an enabling and prohibiting character. Method according to claim 13, characterized in that the function of the LEDs (4) in each section (9) is controlled and supervised by a separate control circuit based on information from the superior The system and diagnostic information from this section (9) and both sections (9) remaining. -8EN 297617 B6 Method according to claim 14, characterized in that the function information of each LED (4) of any one section (9) of the three sections (9) is obtained by a control circuit from three independent sources, namely the control circuit (5) and the control circuit. monitoring the LED function of this one section (9), from bidirectional transverse communication (6) with the control circuit of another arbitrary section (9) of the two remaining LED sections (9), from bidirectional transverse communication (6) with the control circuit of the last third section ( 9) LED, wherein each control circuit of one of the sections (9) receives information transmitted by bi-directional transverse communication (6) about the function of the LEDs (4) of the two remaining LED sections (9) from the current supervision (3) of these adjacent sections (9). Method according to claim 13, characterized in that, irrespective of the information from the master system in the event of failure of one LED lamp section (9), possibly even without the control circuit information of the two remaining sections (9), the control circuits cut off the power (1) LEDs (4) of section (9) with a detected fault. A method according to claim 13, characterized in that, regardless of the information from the master system, in the event of failure of one section (9) at the LEDs of the prohibiting sign and after the control circuit information of the two remaining sections ( 9) the control circuits disconnect the power supply (1) of the LEDs (4) of the detected fault section (9). A method according to claim 13, characterized in that the control circuit with the superior system communicates bidirectionally exclusively via a secure bidirectional data communication (8), which is preferably physically redundant with the concurrent active state. Method according to claim 13, characterized in that the power supply (11) forms three separate supply circuits (12) from two input power systems (10) for three separate sections (9) of the LED lamps, the failure of any one of the two of the input power systems (10) results in the failure of only one of the three separate power circuits (12) of the sections (9) of the LED lamps, so that the LED lamp remains fully functional.